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In the following arrangements, bock is s...

In the following arrangements, bock is slightly displaced vertically down from its equilibrium position and released. Find time period of vertical oscillations. The pulley is light.

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If m is equilibrium tension in string must be mg and spring is stretched by h so that `mg = kh`. If the displace the block downward by a distance A and relesed, it starts executing SHM with amplitude A. During its ocillation we consdier the block at a displacement x below the equilibrium position, if it is moving at a speed b at this position, the pulley will be rotating at an angular speed `omega` given as `omega = v/r`

Thus at this position the total energy of oscillating system is `E_(T) = 1/2mv^(2) + 1/2Iomega^(2) + (1)/(2)k(x+h)^(2) - mgx`
Differentiating with respect to time,
we get `(dE_(T))/(dt) = 1/2m(2v(dv)/(dt)) + 1/2I((1)/(r^(2))) (2v(dv)/(dt)) + 1/2k[2(x+h)(dx)/(dt)] - mg(dx/dt) = 0`
or `mva + (I)/(r^(2)) va + k(x+h)v - mgv = 0` or `a+ ((k)/(m+(I)/(r^(2)))) x = 0` [as `mg = kg`]
comparing above equation with standard differentional equation of SHM we get `omega = sqrt(((k)/(m+(I)/(r^(2)))))`
Thus time period of oscillation is `T = (2pi)/(omega) = 2pisqrt((m+I/(r^(2)))/(k))`
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